CZ7089U1 - Microstrainer filter - Google Patents

Description

Microsieve filter

Technical field

The invention relates to a micro-mesh filter comprising a container in which a rotatable filter drum consisting of a pair of parallel faces interconnected by crossbeams is situated, wherein a filter sheet is situated at the periphery of the filter drum and each filter drum face is associated with a drive roller above the rotary axis of the filter drum. which is wrapped by an endless drive element on which the respective face of the filter drum is suspended, at least one of the two drive pulleys being coupled to the drive.

BACKGROUND OF THE INVENTION

There are currently three known methods of receiving a filter drum of a micro-mesh filter.

The first is a bearing where the filter drum of the micro-mesh filter, or a system including the micro-mesh filter drum, is provided in its axis of rotation with pins which are rotatably mounted in the micro-mesh filter container. Relative advantage of this arrangement is high static and dynamic load-bearing capacity and stiffness, but to be able to take advantage of this advantage it is necessary to use highly efficient and thus very complicated sealing of this arrangement against waste water leakage from micro mesh filter container into filter. However, the main disadvantage of this solution is the problematic removal of sludge from the interior of the filter drum, which for construction reasons must be situated in one of the studs of the filter drum bearing, thereby limiting the removability of sludge and other solid impurities from the interior of the filter drum. This solution also leads to an increase in the axial forces acting on the filter drum, thereby increasing the wear of the filter drum bearing.

The second one is a bearing where the faces of the filter drum formed by the rings are provided with a rolling track on their circumference and each face is suspended on an endless flexible belt wrapped around a single pulley. The pulley is located above the filter drum at each face of the filter drum and is coupled to the drive. The advantage of this solution is the possibility of placing the wastewater inlet into the filter drum and the removal of sludge and other impurities into the free space of the rings of both faces of the filter drum, and thus the possibility of increasing the performance of such a device.

However, this solution also presents a significant disadvantage, which is the low directional stability of the filter drum rotating on a rolling endless flexible belt. This drawback leads to the need for additional directional stabilization of the rotating filter drum inside the micro-mesh filter container, which increases the cost and complexity of the device, while increasing the size of the device and excessively stressing the endless flexible web.

The last known placement of the filter drum inside the micro-mesh filter container is a solution in which the faces are provided

7089 U1 of the filter drum is formed by rings wherein a pair of support rollers abuts the inner drain of each of them in the upper half of this circumference, the outer circumference of which both rings are provided with a rack which is associated with a drive gear coupled to the engine. The advantage of this solution is the absolutely perfect transmission of torque from the drive to the filter drum by a gear transmission and, as in the previous solution, the perfect removal of sludge and other impurities from the filter drum through the free space of the ring faces of the filter drum.

Also, the main disadvantage of this solution is, as in the previous solution, the considerable positional instability of the filter drum inside the vessel, especially during start-up of the device and the shocks resulting from the irregular inflow of waste water.

The object of the invention is to eliminate or at least minimize the disadvantages of the prior art.

The essence of the technical solution

The object of the invention is achieved by placing a filter drum of a micro-sieve filter, which is characterized in that the drive pulley of each filter drum face is associated with an auxiliary pulley above the level of the filter drum rotation axis, wrapped with the same endless drive element as the drive pulley of the filter drum face.

The advantage of this arrangement of the filter drum in the microfilter filter container is a substantial increase in the positional stability of the filter drum even in the case of large irregularities in the waste water inflow.

The drive rollers are preferably rotatably mounted in a micro-mesh filter container, coupled to the drive.

The auxiliary rollers are preferably rotatably mounted in a micro-mesh filter container.

According to a further preferred embodiment, the at least one auxiliary roller is coupled to the drive.

The advantage of this advantageous embodiment is the higher reliability of rotation of the filter drum, especially for large micro-mesh filters.

The endless drive element is preferably formed by a smooth flexible strip, the rolling surfaces of the respective parts of the micro-mesh filter having a convex profile.

The advantage of this embodiment is the simple production of the rolling surfaces of the respective parts of the micro-mesh filter.

According to a further preferred embodiment, the endless drive element is formed by a flexible strip with at least one wedge-shaped protrusion situated along the length of the flexible strip on its rolling surface, the rolling surfaces of respective portions of the micro-mesh filter having a corresponding number of longitudinal grooves with cross section, orientation and location flexible belt.

-2GB 7089 Ul

The advantage of this advantageous embodiment is the reliable guiding of the endless drive element on the respective rolling surfaces of the components of the micro-screen filter, and thus the possibility of producing all the rollers without side flanges, which leads to material savings. A further advantage of this preferred embodiment is the reliable transfer of torque from the drive to the filter drum.

According to a further preferred embodiment, a pressure roller adjoins the outer side of the endless drive element between the drive roller and the auxiliary roller of each filter drum face to increase the wrap angle of the drive roller and the auxiliary roller.

An advantage of this preferred embodiment is to further increase the torque transfer efficiency from the pulleys to the filter drum.

The pressure rollers of both faces of the filter drum are preferably freely rotatable, with the possibility of axial movement, housed in a micro-mesh filter container.

Overview of the drawings

An exemplary embodiment of the invention is shown schematically in the drawing.

Examples of technical solution

The micro-mesh filter comprises a known container (not shown) in which a filter drum 1 is located. The filter drum 1 comprises a pair of known parallel faces 10 which are connected to each other by known transverse beams 11 on which a known filter cloth 12 is mounted. forming the housing of the filter drum 1.

The faces 10 of the filter drum 1 are formed by rings wherein each face 10 of the filter drum 1 is provided with a rolling surface on its outer peripheral surface 100. In the inner space of the ring of one face 10 of the filter drum 1 there is a known not shown waste water inlet to the filter drum 1 of the micro-sieve filter, and a known not shown sludge exit from the inner space of the filter drum 1 not shown, the waste water inlet into the interior of the filter drum 1 and the sludge outlet from the interior of the filter drum 1 are co-located in the interior of one of the rings of the faces 10 of the filter drum 1.

The peripheral surfaces 100 of the faces 10 of the filter drum 1 are wrapped in their lower part by an infinite drive element 13. and in the vertical direction above the faces 10 of the filter drum 1, each drive face 10 of the filter drum 1 is associated with one drive pulley.

2 and one auxiliary roller 20, which are also wrapped by an endless drive element 13, so that the filter drum 1 hangs with its faces 10 on a pair of endless drive elements 13 wrapped around these drive rollers 8 and the auxiliary rollers 20.

In the embodiment shown in the drawing, the non-rotatable drive rollers 6 are mounted on opposite ends of the drive shaft 22, which is rotatably mounted in the upper part of the container

7089 U1 of a micro-screen filter, in a known manner coupled to a drive, such as an electric motor. In another embodiment (not shown), the drive rollers 2 are rotatably mounted on separate pins fixedly mounted in the upper part of the micro-mesh filter container, at least one of which is coupled to the drive in a known manner. In another embodiment (not shown), the drive rollers 2 are rotatably mounted in a micro-mesh filter container in another known manner, at least one of which is coupled to the drive in a known manner.

In the exemplary embodiment shown in the drawing, the non-rotatable auxiliary rollers 20 are mounted at opposite ends of the auxiliary shaft 24, which is rotatably mounted in the upper portion of the microfilter filter container. In another exemplary embodiment (not shown), the auxiliary rollers 20 are rotatably mounted on separate pins fixedly mounted in the upper portion of the microfilter filter container. In a further embodiment (not shown), the auxiliary rollers 20 are rotatably mounted in the micro mesh filter container in another known manner. At least one of the auxiliary rollers 20 housed in the microfilter filter container by any of the above methods is coupled to the drive in a known manner in a known manner (not shown).

In the exemplary embodiment shown in the drawing, the outer surface of the endless drive element 13 of each face 10 of the filter drum 1 rests in the section between the drive roller 2 and the auxiliary roller 20 a pressure roller 23 to increase the wrap angle of the drive roller 2 and this auxiliary roller 20 This leads to an increase in the reliability of rotation of the filter drum

1.

The thrust rollers 23 are freely rotatable and axially displaceable mounted on a common thrust shaft 230 mounted non-rotatable in the upper portion of the microfilter filter container between the drive shaft 22 of the drive rollers 2 and the auxiliary shaft 24 of the auxiliary rollers 20. In another embodiment not shown in the microfilter filter container, they are rotatably mounted on separate pins fixed in the microfilter filter container. In another exemplary embodiment (not shown), the pressure rollers 23 are rotatably mounted in a micro-mesh filter container in another suitable manner. In a further embodiment (not shown), the mounting of the filter drum 1 on the endless drive element 13 is carried out without the pressure rollers 23.

In the embodiment shown in the drawing, the endless drive element 13 is formed by a smooth flexible strip, the rolling surfaces of the respective parts of the micro-mesh filter having a known convex profile (not shown) on these surfaces because of the stability of the endless drive element 13.

In another embodiment (not shown), the endless drive element 13 is provided on its rolling surface in the longitudinal direction, i.e. in the direction of its length, with side-by-side projections of an isosceles trapezoidal cross section. The rolling surfaces of the respective parts of the micro-mesh filter are provided with longitudinal grooves with a cross-section similar to the projections of the endless drive elements 13 and these projections fit into the grooves in the rolling surfaces of the rollers 2 and 20 and the peripheral surface 100 of each of the filter drum faces 10. 1, which leads to a higher one

7089 U1 to the degree of contact between the endless drive element 13 and the rolling surfaces of the respective parts of the micro-screen filter, and thus to more reliable rotation of the filter drum without the need to additionally increase the wrap angle . At least one of the two pulley pairs 2 and 20 associated with the faces 10 of the filter drum 1 is coupled to the drive in a known manner in this embodiment. In a further embodiment (not shown) with an endless drive element 13 formed by a flexible strip with projections, the aforementioned pressure rollers 23 are situated between the drive rollers 2 and the auxiliary rollers 20 as described above.

In another embodiment (not shown), the endless drive element 13 is formed by a chain or other suitable means, the rolling surfaces of the respective parts of the micro-mesh filter being adapted for corresponding contact between these surfaces and the endless drive element 13.

The filter drum 1 is situated between the known transverse and longitudinal guide plates loosely adjacent to the respective outer surfaces of each of the faces 10 of the filter drum 1 for additional stabilization in the transverse and longitudinal directions with high unevenness in the waste water inlet.

Between the faces 10 of the filter drum 1 and the micro-sieve filter container, there are known known sealing elements (not shown) which prevent untreated waste water from entering the treated waste water.

Claims (8)

PROTECTION REQUIREMENTS A microfilter filter comprising a container in which a rotatable filter drum consisting of a pair of parallel faces interconnected by crossbeams is situated, wherein a filter sheet is situated on the periphery of the filter drum and each filter drum face is associated with a driving pulley above the filter drum rotation axis. wrapped by an endless drive element on which the respective face of the filter drum is suspended, at least one of the two drive pulleys being coupled to the drive, characterized in that the drive pulley (2) of each face (10) of the filter drum (1) is above the axis rotation of the filter drum (1) is associated with an auxiliary roller (20), which is wrapped with the same endless drive element (13) as the drive roller (2) of the respective face (10) of the filter drum (1). A micro-sieve filter according to claim 1, characterized in that the drive rollers (2) are rotatably mounted in the micro-sieve filter container and are coupled to the drive. A micro-sieve filter according to claims 1 and 2, characterized in that the auxiliary rollers (20) are rotatably mounted in the micro-sieve filter container. -5GB 7089 Ul A micro-sieve filter according to claims 1 to 3, characterized in that at least one of the auxiliary rollers (20) is coupled to the drive. A micro-mesh filter according to claims 1 to 4, characterized in that the endless drive element (13) is formed by a smooth flexible strip, the rolling surfaces of the respective parts of the micro-mesh filter having a convex profile. A micro-mesh filter according to claims 1 to 5, characterized in that the endless drive element (13) is formed by a flexible strip with at least one wedge-shaped projection situated along the length of the flexible strip on its rolling surface, are provided with a corresponding number of longitudinal grooves with a cross-section, orientation and location corresponding to the extension of the flexible strip. A micro-filter according to claims 1 to 6, characterized in that a pressure roller (13) adjoins the outer side of the endless drive element (13) between the drive roller (2) and the auxiliary roller (20) of each face (10) of the filter drum (1). 23) to increase the wrapping angle of the drive roller (2) and the auxiliary roller (20). A micro-mesh filter according to claim 7, characterized in that the pressure rollers (23) of the two faces (10) of the filter drum (1) are freely rotatable and can be axially moved in the micro-mesh filter container.